Disha NEET Physics Guide for classes 11 and 12.pdf
Intelligent Transport System
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INTELLIGENT TRANSPORT SYSTEMS
P. Rajendra Prasad Naik
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ABSTRACT
The stock of roads, railways, ports, airports and pipelines are proving inadequate to meet the growing demands.
Capacity augmentation is proving to be very costly and and time-consuming, and is soon overtaken by traffic
growth. The four laning programme under the National Highway Development Programme in India, is a example
wherein no sooner the roads were four-laned, many four-lane sections now call for six-laning, or better, call for a
new controlled access Expressway. This innovative approaches are needed to optimize the investments. The
application of Information Technology in transport is receiving world-wide attention in this context. A new
concept, known as the Intelligent Transport Systems, is finding useful application.
Introduction
Intelligent Transport Systems (ITS), also known as
Transport Telematics, are transport systems that apply
modern information technologies to improve the
operation of transport networks. The systems acquire
vast volume of data on various aspects of transport
operations (such as traffic volume, speed,headway,
load carried), process them and apply the result to
guide traffic, improve operations enhance safety and
transport costs.
Application of ITS
ITS can cover a wide variety of applications such as:
(i) Monitoring traffic flow, provide
information to drivers on the congestion on
the road, road closures, alternative routes,
weather conditions and speeds to be
observed. Advanced Traveller Information
Systems (ATIS) gives information to
highway users on traffic jams, road
closures, alternative roads and weather
condition.
(ii) Monitoring incidents on the road, such as
vehicle beak-down and collisions;
(iii) Electronic collection of toll;
(iv) Intelligent Vehicle Highway Systems
(IVHS), in which vehicles are guided
longitudinally and laterally by the use of
electronic devices. The Advanced Vehicle
Control Systems (AVCS) dispense with
human control of vehicles and rely
oncomputers.
(v) Traffic control on urban streets by using
information on traffic flows and adjusting
the signal operations to reduce congestion
and delay.
(vi) Asset Maintenance Management Systems
cover the data on the asset,periodic
condition survey data and use software
packages to optimize maintenance
interventions.
(vii) Public Transport Management Systems
wherein the fleet can be managed
efficiently by analyzing data on vehicle
location, adherence to schedules and
passenger loadings. Demand-Responsive
Public Transport ans Taxis can also be a
part of the system. The use of GIS is
extensively made.
(viii) Truck Transport Management Systems,
wherein the data on vehicle location,
breakdowns, accidents, detention etc. can
be analysed and action initiated to improve
the operations. The use of GIS is extremely
made.
(ix) Electronic Road Pricing System to
decongest the city centers.
Information Technology has been successfully
used for several decades nnow on acquiring
large volume of data on travel patterns in a
city, analyse the data, develop forecasting
models and plan efficient transport plans.
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History of ITS
The origin of the formal ITS program dates back to
the nineteen sixties with the development of the
Electronic Route Guidance System, or ERGS in the
United States, to provide drivers with route guidance
information based on real-time traffic analysis. The
system used special hardware located at various
intersections across the road network, on-board 2-way
devices in vehicles that would form the hub of
communication between the driver and the ERGS
system, and a central computer system that processed
the information received from the remote systems.
During the early seventies, the ERGS program led to
a more sophisticated, automated system comprising
interactive visual digital maps called the Automatic
Route Control System or ARCS. The Urban Traffic
Control System was developed concomitantly,
connecting various traffic signals and computer
generated predetermined signal timings for better
traffic organization.
In Europe, the Program for a European Traffic System
with Higher Efficiency and Unprecedented Safety
(Prometheus) was designed by auto manufacturers and
this was followed by Dedicated Road Infrastructure
for Vehicle Safety in Europe (DRIVE) project, set up
by the European Community.
ITS Developments in Europe, USA and Japan at the turn of thecentury
ITS Taxonomy
The most commonly used classification of ITS is
based on the positioning of the system as given
below.
Vehicle Level
Technologies deployed within vehicles, including
sensors. information processors and displays that
provides information to the driver.
Infrastructure Level
Sensors on and by the side of roads collect
important traffic data Tools of communication
provide drivers with pertinent information to
manage traffic better. These tools include
roadside messages, GPS alerts and signals to direct
traffic flow.
Cooperative Level
Communication between vehicles, and between
infrastructure and vehicles involving a synergic
combination of vehicle level and infrastructure level
technologies.
The commonly adopted functional taxonomy of ITS
is as follows
ATMS, ATIS, AVCS, CVO, APTS, ARTS
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Advanced Traffic Management Systems (ATMS)
integrates rations sub-systems (such as CCTV,
vehicle detection, communications, variable message
systems, etc.) into a coherent single interface that
provides real time data on traffic status and predicts
traffic conditions for more efficient planning and
operations. Dynamic traffic control systems, freeway
operations management systems, incident response
systems etc.
Examples of ATMS
Advanced Traveler Information Systems (ATIS)
provide to users of transportation systems, travel-
related information to assist decision making on tome
choices, estimate travel times, and avoid congestion.
This can be enabled by providing different
information using various technologies such as:
GPS enabled in-vehicle navigation systems
Dynamic road message signs for real time
communication of information on traffic
congestions, bottlenecks, accidents and
alternate route information diving road closures
and maintenance
Website to provide a colour-coded network
map shoving congestion levels on highways
(congestion index).
Examples of ATIS
Advanced Vehicle Control Systems (AVCS) are tools and
concepts that enhance the driver's control of the
vehicle to make travel safer and more efficient. For
example, in vehicle collision warning systems alert the
driver to a possible imminent collision. In more
advanced AVCS applications, the vehicle could
automatically break or steer away from a collision,
based on input from sensors on the vehicle. Both
systems are autonomous to the vehicle and can
provide substantial benefits by improving safety and
reducing accident induced congestion. The
installation of high tech gadgets and processors in
vehicles allow incorporation of software applications
and artificial intelligence systems that control internal
operations, ubiquitous computing, and other programs
designed to be integrated into a greater transportation
system
AVCS
Commercial Vehicle Operations (CVO) comprises an
ensemble of satellite navigation system, a small
computer and a digital radio, which can be used in
commercial vehicles such as trucks, vans, and taxis
This system affords constant monitoring of truck
operations by the central office and provides
traceability and safety.
CVO
Advanced Public Transportation Systems (APTS)
applies state-of-art transportation management and
information technologies to public transit systems to
enhance efficiency of operation and improve safety.
Digital announcement of transit arrival
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It includes real-time passenger information systems,
automatic vehicle location systems, bus arrival
notification systems, and systems providing priority of
passage to buses at signalized intersections (transit
signal priority)
Advanced Rural Transportation Systems (ARTS)
provide information about remote road and other
transportation systems. Examples include automated
road and weather conditions reporting and directional
information. This type of information is valuable to
motorists travelling to remote or aural areas. This has
been widely implemented in the United States and will
be a valuable asset to countries like India, where rural
areas are widely distributed.
ARTS
INTELLIGENT TRANSPORT SYSTEMS TECHNOLOGIES
i. Wireless Communications
Dedicated Short-Range Communications (DSRC) :
It offers communication between the vehicle
and the roadside in specific locations (for
example toll plazas) Applications such as
Electronic Fee Collection (EFC) will operate
over DSRC. It is a sub-set of the RFID -
technology (Radio-frequency identification).
Continuous Air interface Long and Medium range
(CALM) :
Continuous Air interface Long and Medium
range (CALM) provides continuous
communications between a vehicle and the
roadside using a variety of communication
media, including cellular and infra-red links.
CALM will provide a range of applications,
including vehicle safety and information, as
well as entertainment for driver and
passengers.
ii. Computational Technologies:
The CTS (Computational Transportation
Science) fellows will develop technologies in
which sensors, travellers computers , in-
vehicle computers, and computers in the static
infrastructure.
The installation of operational systems and
processors in transportation vehicles have
also allowed software applications and
artificial intelligence systems to be installed.
These systems include internal control of
model based processes, computing and other
programs designed to be integrated into a
greater transportation system.
iii. Floating Car Data/Floating Cellular Data:
Available Floating Car Data Detection
Techniques
Non Real-time:
– Manual surveys.
– Video recording and manual search.
– In-vehicle data recording.
Real-time:
– Automatic Number Plate Recognition (ANPR).
– GPS trace + mobile comms e.g. GSM.
– Radio Signal Triangulation.
– Roadside beacon + dedicated short range tag.
iv. Sensing Technologies:
Sensing systems for Intelligent Transportation
System are vehicle and infrastructure based
networked systems, e.g., Intelligent vehicle
technologies
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Pavement loops are use to sense the
presence of vehicle demand at intersections
and parking lot entrances.
Pressure pads are use to sense the presence
of pedestrians waiting to cross a roadway.
Benefits:
Low Power
Most accurate technology for detecting speed
Traffic Count accuracy Easy installation
v. Inductive loop detection:
one or more loops of wire are embedded
under the road & connected to a control box.
When a vehicle passes over or rests on the
loop, inductance is reduced showing a vehicle
is present.
Benefits:
Established Technology
Not impacted by environmental conditions
Accurate in detecting vehicle presence
Performs well in both high and low volume
traffic.
vi. Video Vehicle Detection:
Video vehicle detection (VVD) is the One of the
most widely used method. Video detection is an
image processor. It consists of a microprocessor-base
CPU and software that analyzes video images. Using
a mouse and interactive graphics, the user places
virtual "detectors”on the video image displayed on a
monitor.
Statistics can be progressively transmitted to a server
for real-time analysis.
Using ITS
ITS is a collective name for a number of
technology-based approaches that are
designed to improve the quality, safety and
efficiency.
One way of categorising these approaches is
into the following application areas:
Traffic management and control
Tolling
Road pricing
Road safety and law enforcement
Public transport travel information and
ticketing
Driver information and guidance
Freight and fleet management
Vehicle safety
Intelligent Transport Systems in INDIA
The ITS program in India is aimed at ensuring
safe, affordable, quick, comfortable, reliable and
sustainable access for the growing urban and
rural population to jobs, education, recreation and
such other needs. A few ITS applications have
been introduced in India in metropolitan cities
like New Delhi, Pune, Bangalore, Chennai etc.
A description of some of the existing applications
of ITS is given below:
Trial of advanced Traffic Management System
This involved a trial run of the fully automated
Traffic Regulatory Management System (TRMS),
involving usage of surveillance cameras in the city of
Chennai. This project involved installing
sophisticated cameras, wireless towers and poles,
under the Rs. 3-crore-State government-funded
project. Automatic Number Plate Reader (ANPR)
cameras were installed in 28 out of 42 vantage points
in the city, while Pan Tilt Zoom' (PTZ) cameras were
deployed in 10 out of 12 busy junctions identified.
The traffic police also plan to install 40 CCTV
cameras at various junctions. This is to warn
motorists who blatantly violate rules and monitor
traffic on arterial roads during peak hours.
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Automated Traffic Control (ATC) ATC has been setup in
many cities in India including Delhi, Pune, Mumbai etc.
Mumbai:
The Area Traffic Control Project of the Mumbai Traffic
Control Branch focused on synchronising major junction
and was implemented through the Mumbai Metropolitan.
Region Development Authority (MMRDA) and Municipal
Corporation of Greater Mumbai (MCGM) with financial aid
from World Bank Modern gadgets such as Speed Check
Guns and Multi Radar C comprising Smart Cameras,Radar
sensor, Screen,Manual control unit, Flash generator, Flash
light, Power Box and Tripod were used in this project.
Chennai:
The Chennai traffic police set up the city's first Automatic
Traffic Control (ATC) system at 26 major traffic signals
around the new secretariat complex. The system monitors
and regulates traffic without any manual intervention and
helps police regulate VIP routes. The ATC is designed to be
capable of changing signal duration in accordance with the
volume of the traffic by analysing the number of vehicles at
three adjoining junctions and synchronism- g the signals.
Manual intervention if required is designed to be performed
from the control room. A VIP movement can be managed
by creating a green corridor by automatically synchronising
the signals along the VIP route.
Advanced Traffic Information System (ATIS)
The objective is to inform road-users of latest traffic
updates and better management of traffic. SMS, Internet
and radio have been employed for updates. The update
protocols in a few Indian cities are as follows
a. Bangalore and Hyderabad
• Internet (june 2008)
This project provides a platform for the public to check the
real time traffic situation at important junctions and arterial
roads, through the net. Real time images of traffic at busy
junctions are available. It covers 40 busy traffic junctions
and the informations are updated every 15 seconds
• SMS(October 2009)
To keep commuters informed about traffic congestion and
bottlenecks in realtime, Bangalore Traffic Police have
made arrangements to send SMS. The facility is available
free of cost to all those who register for it. Everyday two
SITS will be sent during morning and evening peak hours
to the subscribers, indicating congestion points and bottle
necks. In addition, reasons and alternatives will also be
communicated. Additional messages will be sent whenever
there are man-made disruptions in traffic like agitations,
serious accidents etc.
b. Chennai
• FM radios
Traffic updates are being provided on FM radio to convey
critical information such as obstruction and road damage
due to rain.
c. Delhi
• 'The Traffic People' (April 2009)
The Traffic People' provides real time traffic updates to
residents in the Delhi — NCR region. It gives time-to-time
information on traffic situations through websites. Latest
information on traffic jams, processions or rallies resulting
in slow vehicular movement and on any sort of diversion
can be obtain- ed from the website. As of now it provides
updates only during peak hours during mornings and
evenings, but will expand coverage as need arises. They
also share traffic updates with radio channels that makes it
possible to reach a broader audience. An SMS alert
subscription costs about Rs. 99/- per month.
Advanced Public Transportation System (APTS)
One application implemented in APTS area is GPS vehicle
tracking system in public transport buses (Bangalore,
Chennai, Inclose) to monitor vehicle routing and frequency
so that passengers do not have to wait long hours for a bus.
The objective is to provide Global Positioning System
based passenger information system to help passengers
utilise their waiting time at bus stops more efficiently as
well as to reduce the uncertainty and associated frustrations.
Display boards with high quality light emitting diode in
wide-view angle are provided at bus stops so that
passengers can read the information_ It displays the number
and destination of the approaching bus, expected time of
arrival, and messages of public interest.
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The cities selected for implementing BRT include
Ahmedabad, Pune, Rajkot, Bhopal, Indore, Visakhapatnam,
Vijaywada and Jaipur.
a. Pune (Dec 2006)
The city of Pune was the first to experiment with a Bus
Rapid Transit system. The project consists of 13 kms of bus
lanes along the Pune Sastra Road using air conditioned, low
floor Volvo B7RLE buses. The project has achieved
success to certain extent. The funding for the project came
from the Government of India under the Jawaharlal Nehru
National Urban RenewalMission.
b. Ahmedabad
Infrastructure Development Board (GIDB), recognizing that
no single mode would cater to the mobility needs of the city
and that 'Bus' forms the most critical segment of the public
transport system in the Ahmadabad city. GOB has thereby
entrusted the system design task to CEPS University. In
August 2009, the Ahmedabad, India, bus rapid transit
system, termed lanmarg," or people's way, began trial
operations, becoming India's first fully-featured BRT
service with median stations, level boarding, and central
control Janmarg has the potential to help revive the image
of public transport in Ahmedabad and in India The enclosed
stations of the BRT system have become some of the finest
quality public spaces in the city.
c. Chennai Rapid Bus Transit Ways (RBTW)
It is a part of the Medium-term and Long-term Transport
Scheme proposed in the Second Master Plan by CMDA.
This is not a part of Chennai BATS which is proposed on a
separate elevated road that is to be constructed as 15
circular corridors.
The REM is proposed along the following 7 routes,
covering a distance of 100 km, would be taken up in the
Medium-term Transportation Scheme
Rajiv Gandhi Saki (OMR/IT Corridor) [2 ) km]
Taramani Link Road [5 km]
MBI Road [15 km]
Pallavaram - Thoraipakkam Road [15 km]
Sardar PatelRoad [10 km]
NSK Saki (Arcot Road) - KS Road [20 km]
St. Thomas Mount - Poonamalk (Mount.
Ponninville Road) [15 km]
City BRTS
Pune BRTS;1 condor (Katraj- &sawargate
- Hadapsar)
Delhi Delhi BRTS. I corridor and 1 more
planned
Ahmedabad Ahmedabad BRTS; 1 corridor and 17
more under construction
Indore Indore BRTS; 1 corridor
Mumbai Mumbai BATS 7(none are grade
segregated) Under Construction
Systems or lane
Hyderabad Hyderabad BRTS; 2 Corridor
Bangalore Bangalore BRTS;14 corridors
planned
Chennai Chennai BRTS;1 planned
Coimbatore Coimbatore BRTS; I corridor
planned
Jaipur Jaipur BATS; 4 corridors
Madurai Madurai BRTS; 2 corridors
Nagpur Nagpur BRTS; 1 corridor
Vijayanda Vijayavada BATS; 2 corridor
Visakhapatnam Visakhapatnam BRTS; 2 corridor
Electronic Toll Collection (ETC)
The Electronic Toll Collection (ETC) is designed to
detente if a car is registered in a toll payment program,
alert enforcers of toll payment violations, and debit the
participating account With ETC, these transactions can
be performed while vehicles travel at near highway
cruising speed ETC is fast becoming a globally
accepted method of toll collection, a trend greatly aided
by the growth of irateroperablility ETC technologies.
Technologies used in ETC are Automatic Vehicle
Identification (AVI), Automatic Vehicle Classification
(Avg, Video Enforcement Systems (VES) and Vehicle
Positioning System (VPS) systems are deployed in the
following cities in India:
Toll collection in INDIA
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Advanced Parking management
State-of-art packing management system is set up by
the New Delhi Municipal Council at Palika Parking in
Connaught Place. This system allow vehicle users to
be guided by a wide range of sensors, lights,
signboards and directional displays to the closest
vacant car space existing in the parking lot and
c;cualely for identifying their car location at the time
of exit. Apart from automatic online guidance at
junctions, zone-wise sub-division of areas will assist
easy identification. The guidance system operate
throughout the three levels of parking at Palika, which
has a capacity for 1,050 cars and 500 scooters.
Issues and challenges of ITS in India
The rapidly advancing economy of India, in par with the
rest of the world has resulted in a phenomenal increase in
use of personal automobiles on Indian urban roads.
In 2001, India had 35 cities with a population of more than
one million people. The heterogeneity of economy and the
physical limit on how much additional infrastructure a city
can hold complicate transport management further.
At present, it can be seen that the penetration of ITS in
Indian road scenario is relatively less and much more is
needed to be done. To make this a reality, there is a need for
more systematic approach to the ITS implementation.
Some of specific actions required to meet the challenges to
ITS in India include:
Evolving a national ITS standard for different ITS
applications and their components
Setting up a national ITS clearinghouse that
documents all ITS projects with details on the
design, implementation, lessons learned/best
practices,and cost-benefit details
Setting up fully functional Traffic Management
Centres for coordinating the urban and regional ITS
activities,
Developing and implementing automated traffic
data collection methodologies,
Developing a national ITS data archive,
Fostering more interaction between academia,
industries and governmental agencies to generate
more interest and in turn projects in the ITS area.
Conclusions
India's ITS cannot be entirely modelled on the
existing successfulITS of other nations due to basic
cultural, geographic and practical differences
amongst the countries. The existing concepts have
to be thoroughly understood in order to modify
them to fit the Indian traffic scenario.
A plethora of issues and challenges have to be
tackled before India can have a fully operating ITS
system. The main challenges perceived include
Establishing ITS standards applicable throughout
the urban and rural sections of India
Designing an ITS that encompasses the
heterogeneous vehicle population
Locatio
n
Name of
roadway
Type of
roadway
Owned
by
Operated
by
Khazag
pur
NH-6 tall
road
Highway NHAI Toll Trax
Toll
Collection
System
Delhi Delhi-
Gurgaon
Expresswa
y
Highway NHAI Metro
Electronic
Toll
Collection
Systems
Chennai IT corridor Highway TNRD
C
Electronic
Tolling
with
future
pIans for
smart
cards
Figure 47: Advancedongoingparking
managementsetupatpalikabazaar,
Delhi
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Developing a comprehensive data collection system
Establishment of a Data Centre
Setting up active interaction between academia,industries and governmental agencies
Government setting up rules and regulations of traffic that will aid in ITS implementation
To meet the challenges in setting up a comprehensive traffic management system, the following tasks have to be
carded out.
Measurement and monitoring the performance of existing transportation management systems throughout the
country;
Establishing aggressive, yet achievable, near and long-term performance goals for transportation systems;
Optimizing the performance of transportation network through the use of real-time data, predictive traffic models,
improved integration between individual systems, and other state-of-art tools and strategies for improving safety,
mobility and the environment.
It is vital to plan key initiatives and activities which advance and improve the development and use of ITS
in India. These include activities addressing the Global Navigation Satellite System (GNSS), encouragement of
international standards development through liaison with the International Organization for Standards, work force
development/training, and improved supply chain management processes in a sustainable fashion.
References: